Immunomorphometric studies of proteinuria in individual deep and superficial nephrons of rats.

Heterogeneity of structure and function among nephrons is a well-recognized feature of chronic renal diseases. However, only a small number of superficial nephrons per kidney are accessible for micropuncture analysis and relationships of proteinuria to structural change in individual nephrons of experimental models are not clearly established. To directly evaluate proteinuria in many individual nephrons, we developed an immunomorphometric method of analysis. This method is based on the uniformly abundant renal synthesis of Tamm-Horsfall protein (THP) in the thick ascending limb of Henle's loop (TAL). Luminal rabbit immunoglobulin G (IgG) deposits are formed in TALs of proteinuric nephrons in rats injected with heterologous IgG anti-THP antibodies. This immunomorphometric luminal deposit method of assessing proteinuria was previously validated through analysis of heterologous immune complex nephropathy. Glomerular dysfunction in several models-spontaneously hypertensive rats (SHR), aging Sprague-Dawley (SD) rats, rats with adriamycin nephropathy (ADR), and rats subjected to subtotal nephrectomy (NX)-was characterized by immunomorphometric analysis after injection of anti-THP antibodies. Luminal IgG deposits were used to identify nephrons with increased proteinuria. Nephrons were identified histologically as either long looped (LL) or short looped (SL), and frequency of luminal deposits in these nephrons was determined. Glomerular size and sclerosis in deep and superficial zones of renal cortex were determined. Luminal deposits in LL nephrons were more frequent than luminal deposits in SL nephrons in SHRs (p < .001) and aging rats (p < .001) and SL nephrons in ADR rats (p < .02). Whole kidney levels of albuminuria correlated closely with the frequency of luminal deposits in both LL and SL nephrons of SHRs and ADR rats and in LL nephrons of aging rats (p < .005). In contrast, LL and SL deposits were equal in NX rats and did not correlate with albuminuria. A majority of luminal deposits extended beyond the first medullary TAL zone of NX rats, but was confined to this zone in the other 3 models. Deep cortical glomeruli were larger with more glomerulosclerosis than superficial cortical glomeruli. Albuminuria correlated with sclerosis of both deep (p < .002) and superficial (p < .01) glomeruli in NX rats, but not in the other three models. These studies provide a detailed characterization of a new method that allows comparison of proteinuria derived from deep and superficial nephrons. They also provide evidence that pathogenesis of the glomerulosclerosis in NX rats differs from that of the other three models. Glomerulosclerosis was closely linked to the overall level of albuminuria in NX rats, but not to luminal deposits. In the other three models, albuminuria and luminal deposits were closely linked but did not correlate with glomerulosclerosis. Furthermore, LL and SL nephron proteinuria of NX rats was comparable while LL proteinuria was markedly greater than SL proteinuria in the other three models. The luminal deposit method provides a new way to analyze heterogeneity of proteinuria among nephrons and the mechanisms underlying structural change in experimental glomerular diseases.

Inhibition of calcium oxalate crystal growth in vitro by uropontin: another member of the aspartic acid-rich protein superfamily.

The majority of human urinary stones are primarily composed of calcium salts. Although normal urine is frequently supersaturated with respect to calcium oxalate, most humans do not form stones. Inhibitors are among the multiple factors that may influence the complex process of urinary stone formation. We have isolated an inhibitor of calcium oxalate crystal growth from human urine by monoclonal antibody immunoaffinity chromatography. The N-terminal amino acid sequence and acidic amino acid content of this aspartic acid-rich protein, uropontin, are similar to those of other pontin proteins from bone, plasma, breast milk, and cells. The inhibitory effect of uropontin on calcium oxalate crystal growth in vitro supports the concept that pontins may have a regulatory role. This function would be analogous to that of other members of the aspartic acid-rich protein superfamily, which stereospecifically regulate the mineralization fronts of calcium-containing crystals.

Studies of glomerular mesangial uptake and processing of macromolecules. I. Effect of polyvinyl alcohol-induced macrophages on uptake of iron dextran.

The influence of prior glomerular mesangial uptake of a macromolecule that induces the infiltration of macrophages (M phi) into the mesangium on the uptake of a second macromolecule by the mesangium was studied in inbred Lewis rats. Renal transplantation of kidneys from rats previously injected with polyvinyl alcohol (PVA) was performed to avoid the potential influences of ongoing uptake of PVA and altered host milieu on the glomerular uptake of iron dextran (ID), a macromolecule that localizes primarily in the intrinsic mesangial cells of unmodified rats. In contrast to that in the recipient's native kidney, the uptake of ID was markedly increased in the glomeruli in kidneys previously exposed to PVA. This enhanced uptake was the consequence of the phagocytic activity of mesangial M phi elicited by and containing PVA since the site of increased ID content was shown by ultrastructural studies to be within mesangial M phi. Isogeneic renal transplantation per se did not influence mesangial function since the glomerular uptake of ID in donor and recipient kidneys was the same when donors were normal rats. In addition to the enhanced uptake of ID into lysosomes by mesangial M phi these cells were also much more active in the further processing of ID to ferritin particles within the cytoplasm than were intrinsic mesangial cells. These studies demonstrate that M phi attracted to the mesangium by a stimulus such as PVA may have important effects on the consequences of additional challenges to the mesangium.